Optical transport having full and flexible bandwidth and channel utlization

ABSTRACT

Optical nodes in an optical network may provide directionless, colorless, contentionless, and gridless transmission, reception, and switching of optical signals in which a non-fixed number of optical channels and a non-fixed bandwidth for each optical channel is used. Optical nodes can use the full extent of the optical bandwidth due to the absence of channel spacing.

BACKGROUND

In an optical network, Dense Wavelength Division Multiplexing (DWDM)permits the multiplexing of multiple optical carriers onto a singleoptical fiber by using different wavelengths of laser light. DWDM cancarry more optical channels compared to, for example, Coarse WavelengthDivision Multiplexing (CWDM). As a result, DWDM is used in opticalnetworks in which denser optical channel spacing is needed.

According to DWDM, each transport channel has only one optical carrierthat occupies a fixed optical bandwidth. Since the total usable opticalbandwidth of an optical fiber is fixed, a DWDM system has a fixed numberof total optical channels. For example, the total usable bandwidth of anoptical fiber may be about 5-10 THz. In this instance, a DWDM system canhave a fixed number of optical channels, such as a 96-channel system ora 128-channel system. The fixed optical bandwidth also includesbandwidth to separate adjacent optical channels, which is known aschannel spacing. For example, 10-Gb/s optical systems may have a channelspacing of 100 GHz or a channel spacing of 50 GHz. Additionally,according to the DWDM system, a central frequency of an optical channelis anchored to a frequency grid defined by a standard body, such as theInternational Telecommunication Union (ITU).

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a diagram illustrating an exemplary embodiment of an opticalnetwork in which an optical transport system having full and flexiblebandwidth and channel utilization may be implemented;

FIG. 1B is a diagram illustrating components of an exemplary embodimentof a transmitting-side of an optical node depicted in FIG. 1A;

FIG. 1C is a diagram illustrating components of an exemplary embodimentof a receiving-side of the optical node depicted in FIG. 1A;

FIG. 1D is a diagram illustrating an exemplary embodiment of an add-dropmultiplexer that may be included in an optical node;

FIG. 2 is an exemplary optical network including add-drop multiplexersand transponders;

FIG. 3 is a flow diagram illustrating an exemplary process to set up anoptical channel;

FIG. 4 is a flow diagram illustrating an exemplary process to defragchannel allocation to achieve optimal spectral usage;

FIG. 5 is a flow diagram illustrating an exemplary process to set up anoptical channel based on light path distance; and

FIG. 6 is a diagram illustrating unused bandwidth between opticalchannels.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

The following detailed description refers to the accompanying drawings.The same reference numbers in different drawings may identify the sameor similar elements. Also, the following detailed description does notlimit the invention.

According to an exemplary embodiment, the transport system of an opticalnetwork permits bandwidth of a transport channel to be dynamically setdepending on the particular light-path and network traffic demands.According to an exemplary embodiment, the central frequency of thetransport channel need not be anchored to a fixed optical frequency grid(e.g., gridless). In this regard, the transport system will not have afixed total number of transport channels nor a fixed total number ofoptical carriers. By way of example, according to a fixed-grid design, a1 Terabit/second (Tb/s) system can use 500 Gigahertz (GHz) of opticalbandwidth since optical carrier spacing is fixed at 50 GHz. In contrast,according to a gridless design, a 1 Tb/s system may only use 320 GHz ofbandwidth when no channel spacing is used and when the modulation formatfor each optical carrier is 32 Gigabaud (GBaud). In addition, accordingto an exemplary embodiment, the transport system of an optical networkmay use the unused portion of optical spectrum (e.g., 180 GHz ofbandwidth, according to the above-mentioned example) to supportadditional optical channels.

According to an exemplary embodiment, the transport system may includeoptical nodes that are able to switch any transport channel regardlessof its bandwidth and central frequency. According to an exemplaryembodiment, an optical node may include an add/drop multiplexer, such asa Reconfigurable Optical Add-Drop Multiplexer (ROADM), that is able toswitch any transport channel regardless of its starting frequency,ending frequency and central frequency. According to an exemplaryimplementation, the ROADM may have a colorless, directionless,contentionless, and gridless architecture. The ROADM may switch opticalchannels for which channel spacing is not used. As a result, theadditional bandwidth resulting from the absence of guard bands may beused for additional optical channels, as described further below.

According to an exemplary embodiment, an optical node may include atransponder or a transceiver that is able to set various parametersaccording to the network traffic demand in a light path. The parametersmay include the data rate of each optical channel, the number of opticalcarriers to be used in each optical channel, the modulation format ofeach optical channel, the total bandwidth of each optical channel, andthe starting and ending frequencies of each optical channel. Thetransponder may include a single-carrier transmitter and/or amulti-carrier transmitter with tunable optical carrier so that atransport channel may be carried by a single carrier or multiplecarriers (e.g., a super channel). Additionally, the transponder mayinclude a single-carrier receiver or a multi-carrier receiver and atransport re-assembler for receiving a transport channel carried by thesingle carrier or multiple carriers.

According to an exemplary embodiment, an optical node may include anetwork management system. The network management system may configurean optical node in accordance with the features described herein. Forexample, the network management system may configure the optical node asit pertains to optical channel configuration (e.g., bandwidth assignedto the transport channel, the number of optical carriers, the modulationformat, the data rate, the starting and ending frequency of the opticalchannel, etc.), power configuration, etc.

According to an exemplary embodiment, the optical network may include anetwork management system that manages the configuration of the opticalnetwork including the optical nodes. The network management system mayidentify network state information, resource availability and/orallocation, and other parameters pertaining to the optical network. Thenetwork management system may communicate with the network managementsystem of an optical node regarding these parameters as such parametersrelate to the features described herein. The optical network mayoptimize channel capacity, total capacity, spectral efficiency, reachdistance, etc.

FIG. 1A is a diagram illustrating an exemplary embodiment of an opticalnetwork in which an optical transport system having full and flexiblebandwidth and channel utilization may be implemented. As illustrated inFIG. 1A, an exemplary environment 100 includes an optical network 105including optical node 110-1 through optical node 110-X, in which X>1(referred to individually as optical node 110 or collectively as opticalnodes 110), optical link 115-1 through optical link 115-Z, in which Z>1(referred to individually as optical link 115 or collectively as opticallinks 115), and network management system 125. Environment 100 alsoincludes device 120-1 through device 120-Z, in which Z>1 (referred toindividually as device 120 or collectively as devices 120). Devices 120may be communicatively coupled to optical network 105 via various accesstechnologies.

The number of devices (which includes optical nodes) and theconfiguration in environment 100 are exemplary and provided forsimplicity. According to other embodiments, environment 100 may includeadditional devices, fewer devices, different devices, and/or differentlyarranged devices than those illustrated in FIG. 1A. For example,environment 100 may include intermediary devices (not illustrated) topermit communication between devices 120 and optical network 105.

Optical network 105 is an optical network. For example, optical network105 may include a synchronous optical network. Optical network 105 maybe implemented using various topologies (e.g., mesh, ring, etc.).According to an exemplary embodiment, optical network 105 is a long-hauloptical network (e.g., long-haul, extended long-haul, ultra long-haul).According to other embodiments, optical network 105 is an opticalnetwork other than a long-haul optical network. Optical node 110 is apoint in optical network 105. For example, optical node 110 may be anoptical regeneration node, an optical transmitting/receiving node, or anoptical switching node. Optical node 110 may be implemented as a DWDMsystem. Optical link 115 is an optical fiber (e.g., nonzerodispersion-shifted fiber, etc.) that communicatively couples opticalnode 110 to another optical node 110.

Device 120 may include a device having the capability to communicatewith a network (e.g., optical network 105), devices and/or systems. Forexample, device 120 may correspond to a user device. For example, theuser device may take the form of a portable device, a handheld device, amobile device, a stationary device, a vehicle-based device, or someother type of user device. Additionally, or alternatively, device 120may correspond to a non-user device, such as, a meter, a sensor, or someother device that is capable of machine-to-machine (M2M) communication.

Network management system 125 may manage the configuration of opticalnetwork 105 including the optical nodes 110. Network management system125 may permit administrators to monitor, configure, etc., opticalnetwork 105. Network management system 125 may be capable of identifyingnetwork state information, resource availability and resourceallocation, and/or other parameters pertaining to optical network 105.Network management system 125 may communicate with a network managementsystem (not illustrated) of an optical node 110 regarding theseparameters as such parameters relate to the features described herein.For example, network management system 125 may assign bandwidth to atransport channel based on the bandwidth needed, the distance to reach(e.g., based on a distance between source and destination optical nodes110), the time the bandwidth is needed, optimization of spectral usage,as well as other parameters described. Network management system 125 mayinclude one or more network devices (e.g., a server, a computer, etc.).Network management system 125 may be implemented in a centralized or adistributed fashion.

FIG. 1B is a diagram illustrating components of an exemplary embodimentof a transmitting-side of one or more of the optical nodes 110 depictedin FIG. 1A. As previously described, the transport system, among otherthings, may not use channel spacing. As a result, the additionalbandwidth resulting from the absence of guard bands (i.e., channelspacing) may be used for additional optical channels. However, opticalnodes in existing DWDM systems and WDM systems are configured both interms of operation and available node resources (e.g., number oftransmitters, receivers, transponders, switches, ports, etc.) accordingto a fixed system (e.g., in terms of central frequency, number ofoptical channels, etc.), as previously described. According to anexemplary embodiment, optical node 110 illustrated in FIG. 1B may beconfigured both in terms of operation and available node resources forfull and flexible bandwidth and channel utilization.

According to another exemplary embodiment, not illustrated, a legacyoptical node may be expanded in terms of node resources (e.g., addingtransponders, ports, switches, line amplifiers, etc.) and updated interms of operation to make use of the various features described herein.For example, an optical node of a fixed-channel system (e.g., a40-channel transport system, an 80-channel transport system, a96-channel transport system, etc.) has a particular number oftransponders, ports, switches, line amplifiers, etc., to support thefixed-channel system. However, as described herein, by using, amongother things, a gridless transport system in which channel spacing isnot used, the available bandwidth (e.g., C-band, L-band, S-band, etc.)is increased. Therefore, in terms of a legacy optical node, the numberof node resources could be expanded (i.e., increased in number relativeto a fixed-channel optical node) to accommodate the additional availablebandwidth.

As illustrated in FIG. 1B, optical node 110 includes a data source 105,a laser 110, a carrier generator 115, modulators 120-1 through 120-T, inwhich T>1 (referred to individually as modulator 120 or collectively asmodulators 120), a network management module 127, and a ROADM 135. Asfurther illustrated, optical links 115-1 through 115-3 are coupled toROADM 135. The number of optical links 115 is exemplary and provided forsimplicity.

The number of components and the configuration (e.g., connection betweencomponents) are exemplary and provided for simplicity. According toother embodiments, optical node 110 may include additional components,fewer components, different components, and/or differently arrangedcomponents than those illustrated in FIG. 1B. For example, thetransmitting-side of optical node 110 may include a power source, anoptical amplifier (e.g., Erbium Doped Fiber Amplifier (EDFA), Ramanamplifier, etc.), digital signal processing (DSP) (e.g., forward errorcorrection (FEC), equalization, filtering, etc), an optical transceiver,etc. Additionally, for example, the transmitting-side of optical node110 may not include carrier generator 115 and multiple lasers 110 may beused.

Data source 105 may provide data that is to traverse optical node(s) 110in optical network 105. Laser 110 may include a laser (e.g., a cooledlaser). According to an exemplary embodiment, laser 110 may include atunable laser (e.g., a Distributed Feedback (DFB) laser, anExternal-Cavity Laser (ECL), a Sampled Grating Distributed BraggReflector (SGDBR) laser, etc.). Carrier generator 115 may includecomponents (e.g., a Photonic Integrated Circuit (PIC) or other knownmulticarrier generating architectures) to produce a single carrieroptical channel and/or a multicarrier optical channel, such as asuper-channel.

Modulators 120 may include optical modulators to provide a modulationformat in terms of constellation (e.g., binary, quaternary, 8-ary,16-ary, higher order constellations, etc.), manner of modulation (e.g.intensity, phase, frequency, polarization), etc.

Network management module 127 may include logic to manage transportchannels and signaling. For example, network management module 127 mayselect bandwidths for optical channels (i.e., starting frequencies andending frequencies) without being anchored to a fixed optical frequencygrid, optimize channel capacity, total capacity, spectral efficiency,reach distance, etc. Network management module 127 may identify whetheran optical channel is single-carrier or multi-carrier, the type ofmodulation for each optical carrier, and the data rate. Networkmanagement module 127 may also correlate performance and alarminformation across all optical carriers.

Network management module 127 may include one or multiple processors,microprocessors, multi-core processors, application specific integratedcircuits (ASICs), controllers, microcontrollers, and/or some other typeof hardware logic to perform the processes or functions describedherein. Network management module 127 may configure the operation ofoptical node 110 based on information received from network managementsystem 125 and/or optical network requirements (e.g., network trafficdemands, resources available, etc.).

ROADM 135 is an add/drop multiplexer. ROADM 135 may include a colorless(e.g., any wavelength to any add/drop port), a directionless (e.g., anywavelength to any degree), a contentionless (e.g., any combination ofwavelengths to any degree from any port), and a gridless (e.g. no fixedfrequency) architecture. ROADM 135 may support any portion of theoptical spectrum provided by the optical network, any channel bit rate,and/or any modulation format. ROADM 135 is described further below.

According to an exemplary process, as illustrated in FIG. 1B, thetransmitting-side of optical node 110 may output optical signals (e.g.,optical signal outputs 140-1 through 140-3) to optical links 115, whichmay traverse light paths in optical network 105. The number of outputoptical signals is exemplary and provided for simplicity.

FIG. 1C is a diagram illustrating components of an exemplary embodimentof a receiving-side of one or more of the optical nodes 110 depicted inFIG. 1A. According to an exemplary embodiment, optical node 110illustrated in FIG. 1C may be configured both in terms of operation andavailable node resources for full and flexible bandwidth and channelutilization. According to another exemplary embodiment, not illustrated,a legacy optical node may be expanded in terms of node resources (e.g.,adding transmitters, receivers, ports, transponders, switches, etc.) andupdated in terms of operation to make use of the various featuresdescribed herein.

As illustrated, optical node 110 includes network management module 127,a ROADM 150, receivers 155-1 through 155-T, in which T>1 (referred toindividually as receiver 155 or collectively as receivers 155), and adata processor 160. As further illustrated, optical links 115-1 through115-3 are coupled to ROADM 150.

The number of components and the configuration (e.g., connection betweencomponents) are exemplary and provided for simplicity. According toother embodiments, optical node 110 may include additional components,fewer components, different components, and/or differently arrangedcomponents than those illustrated in FIG. 1C. For example, optical node110 may include a power source, an optical amplifier (e.g., EDFA, Ramanamplifier, etc.), DSP, a transceiver, etc.

Network management module 127 may include logic to manage transportchannels and signaling, as previously described. Network managementmodule 127 may correlate multi-carriers to a transport channel, such aswith a super-channel. Network management module 127 may also managefailures pertaining to a transport channel. For example, networkmanagement module 127 may identify when an optical carrier(s) may needto be re-transmitted (e.g., due to the failure) by a source or atransmitting optical node 110.

ROADM 150 may include a ROADM similar to that described above (i.e.,ROADM 135). Receivers 155 may include optical receivers or transponders.Data processor 160 may include logic to convert optical signals 140 toconstruct frames, packets, or other type of data containers.

FIG. 1D is a diagram illustrating an exemplary embodiment of an add-dropmultiplexer, such as ROADM 135/150 that may be included in one or moreof optical nodes 110. As illustrated, ROADM 135/150 may include, amongother components, flexible spectrum selective switches (FSSSs) 175-1through 175-4 (referred to individually as FSSS 175 or collectively asFSSSs 175, power splitters 180-1 through 180-4 (referred to individuallyas power splitter 180 or power splitters 180), and add/drop ports 185.According to other embodiments, ROADM 135/150 may have a differentdegree (i.e., other than a 4-degree ROADM).

The number of components and the configuration (e.g., connection betweencomponents) are exemplary and provided for simplicity. According toother embodiments, ROADM 135/150 may include additional components,fewer components, different components, and/or differently arrangedcomponents than those illustrated in FIG. 1D. For example, ROADM 135/150may include a channel monitor and/or an error detector. Additionally,the number of components (e.g., add/drop ports 185, etc.) may be varydepending on the non-fixed transport system. According to an exemplaryimplementation, ROADM 135/150 may take the form of a ROADM blade.According to an exemplary embodiment, ROADM 135/150 is colorless,directionless, contentionless, and gridless.

FSSS 175 may include a spectrum selective switch that, among otherthings, uses the available bandwidth due to the absence of channelspacing for full and flexible channel utilization. FSSS 175 may alsohave grid-free capability. FSSS 175 may be able to switch any opticalchannel regardless of its bandwidth and central frequency. FSSS 175 mayalso accommodate other features pertaining to the transport systemdescribed herein. In this regard, FSSS 175 is distinguishable from aWavelength Selective Switch (WSS) that is used in a conventional ROADM.

Power splitter 180 may include an optical power splitter and/or anoptical power combiner that is/are color-agnostic, directionless, andcontentionless. Power splitter 180 may provide for splitting and/orcombining of optical signals in optical fibers. Add/drop ports 185 areports for adding and dropping optical signals. Expanded add/drop ports190 are ports for adding and dropping optical signals. For example,ROADM 135/150 may include expanded add/drop ports 190 when ROADM 135/150is upgraded from a fixed-channel transport system to a non-fixed channeltransport system. Although not illustrated, other components of ROADM135/150 may be expanded. According to another example, when ROADM135/150 is not upgraded (e.g., from a fixed-channel transport system),ROADM 135/150 may not include expanded add/drop ports 190.

Referring to FIG. 1D, assume that there is no spectral barrier betweenoptical channels and that the total spectral width of the transportsystem is 6 Terahertz (THz). In comparison to a fixed 120-channelsystem, in which each optical channel occupies 50 GHz of opticalbandwidth, in this example, each optical channel may occupy only 32 GHzof optical bandwidth because there is no channel spacing. As a result,the 120 channels may be packed into approximately 3.84 THz of opticalspectrum instead of 6 THz (e.g., assuming a 32 GBaud symbol rate foreach optical channel). In view of the remaining available opticalbandwidth, 67 additional optical channels may be packed into theremaining spectral bandwidth, which translates into an increase of 56%,relative to a fixed-frequency 120-channel system.

ROADM 135/150 (e.g., FSSS 175) is capable of using the availablespectral bandwidth in a colorless, directionless, contentionless, andgridless framework. Additionally, as previously described, the totalnumber of optical channels in the transport system is not fixed, thedata rate of each optical channel is not fixed, the number of opticalcarriers for each optical channel is not fixed, the central frequency ofan optical channel is not adherent to a fixed frequency grid, and thebandwidth and the number of optical carriers of each optical channel maybe dynamically adjusted based on network traffic demands, availableresources, etc.

FIG. 2 is an exemplary optical network 200 including optical nodes 210-Bthrough 210-K in which each optical node 210 includes ROADM 135/150 andtransponders (TP) 205. Exemplary processes pertaining to an exemplaryembodiment of a transport system is described in reference to FIGS. 2,3, 4 and 5. The exemplary processes described in FIGS. 3, 4, and 5 maybe performed reactively or proactively. By way of example, an exemplaryprocess may be performed periodically or aperiodically, in response to achange in network topology (e.g., new light paths added to the opticalnetwork, additional optical nodes, etc), in response to a change innetwork state (e.g., available network resources, etc.), etc.

According to an exemplary embodiment, the exemplary processes may beperformed by network management system 125. According to anotherembodiment, the exemplary processes may be performed by a combination ofnetwork management system 125 and network management module 127.According to yet another exemplary embodiment, the exemplary processesmay be performed by network management module 127.

According to an exemplary embodiment, network management system 125and/or network management 127 may perform a process based on one ormultiple processors, microprocessors, multi-core processors, applicationspecific integrated circuits (ASICs), controllers, microcontrollers,and/or some other type of hardware logic.

FIG. 3 is a flow diagram illustrating an exemplary process 300 to set upan optical channel.

In block 305, a channel data rate for a traffic flow demand isdetermined. For example, assume network management system 125 receives atraffic demand request. Referring to FIG. 2, according to an exemplaryscenario, the traffic demand request includes a request for a 700Gigabits/second (Gb/s) optical channel from optical node 210-B tooptical node 210-K.

Referring back to FIG. 3, in block 310, optimal light paths(s) areidentified based on the optical end nodes. For example, networkmanagement system 125 may identify candidate (shortest) light paths fromoptical node 210-B to optical node 210-K. Referring to FIG. 2, assumethat optical node 110 identifies light path A-B-C-F-K; light pathA-E-H-K; and light path A-G-H-K.

Referring back to FIG. 3, in block 315, the modulation format for eachcarrier and the number of carriers for each candidate light path isselected. For example, network management system 125 selects themodulation format based on the reach distance of each candidate lightpath. Network management system 125, in addition to, or instead of, mayuse other factors (e.g., available bandwidth, etc.) for selecting themodulation format. In this example, network management system 125selects Dual Polarization Quadrature Phase Shift Keying (DP-QPSK) as themodulation format. Additionally, in this example, network managementsystem 125 selects seven optical carriers in which each optical carrieris allocated 25 Gigahertz (GHz).

In block 320, the total bandwidth needed for each candidate light pathbased on the selected modulation format is determined. In this example,network management system 125 determines the total bandwidth as being175 GHz (i.e., 25 GHz×7 optical carriers).

In block 325, the available bandwidth for each candidate light path forthe optical channel is searched based on the total bandwidth. Forexample, network management system 125 searches the available bandwidthwith respect to other nodes (e.g., optical nodes 210) along thecandidate light paths based on the total bandwidth of 175 GHz. In thisexample, network management system 125 finds available bandwidth forlight path A-B-C-F-K wide-open and for light path A-E-H-K availablebandwidth between 192.320 THz to 193.200 THz. However, networkmanagement system 125 does not find 175 GHz of available bandwidth forlight path A-G-H-K.

In block 330, a light path is selected from the candidate light path(s).For example, network management system 125 selects the best (e.g.,optimal) light path from the candidate light paths A-B-C-F-K andA-E-H-K. In this example, network management system 125 selects lightpath A-E-H-K over light path A-B-C-F-K because light path A-E-H-K is ashorter distance. Additionally, or alternatively, network managementsystem 125 may select a particular light path as the optimal light pathbased on other considerations, such as modulation format, availablebandwidth, spectral efficiency, etc.

In block 335, the optical channel is set. For example, networkmanagement system 125 configures the optical channel along the selectedlight path A-E-H-K via network management module 127. The traffic demandrequest is then satisfied via the resources allocated.

Although FIG. 3 illustrates an exemplary process 300 for setting up anoptical channel, according to other implementations, process 300 mayinclude additional operations, fewer operations, and/or differentoperations than those illustrated in FIG. 3 and described.

FIG. 4 is a flow diagram illustrating an exemplary process 400 to defragchannel allocation(s) to achieve optimal spectral usage. For example,assume that a new optical channel has to be added, but an existingoptical bandwidth and channel allocation imprint pertaining to a lightpath does not provide sufficient contiguous bandwidth for the newoptical channel. According to an exemplary embodiment, networkmanagement system 125 may defrag or rearrange optical channelallocation(s) to create sufficient contiguous bandwidth for the newoptical channel. By way of example, assume that unused bandwidth existsbetween optical channels, as illustrated in FIG. 6.

In block 405, a bandwidth allocation of an existing network bandwidthusage pattern is examined. For example, network management system 125identifies the existing bandwidth/channel allocation pertaining to alight path. For example, network management system 125 identifies theexisting bandwidth/channel allocation for each optical node 210 alonglight path B-C-D. According to an exemplary embodiment, the examinationof the bandwidth usage pattern pertains to the overall spectrum and on aper-channel basis. In this example, FIG. 6 may represent thebandwidth/channel allocation imprint for optical node 210-B. Opticalnode 210-C and optical node 210-D may have their own uniquebandwidth/channel allocation imprint.

In block 410, it is determined whether at least one new bandwidthlocation for the optical channel is available. For example, based on theexamination of bandwidth/channel allocation imprints pertaining tooptical nodes 210-A-B-C, network management system 125 may identifywhether there is sufficient available, unused bandwidth spectrum for thenew optical channel based on shifting optical channel(s) to a newbandwidth location(s). Depending on, among other considerations, theamount of bandwidth needed for the new optical channel and the existingbandwidth/channel allocation imprints, network management system 125 mayselect an optical channel to be assigned to a new bandwidth location.Once an optical channel is selected, one or multiple carriers may beassigned to the new bandwidth location depending on the optical channel.

According to this example, it may be assumed that network managementsystem 125 determines an optical channel may be assigned to a newbandwidth location. Thus, network management system 125 determines thatthere is a new bandwidth location for an optical channel (block410—YES), and process 400 continues to block 415. According to anotherexample, if network management system 125 determines, for example, thatthere is not sufficient available, unused bandwidth between opticalnodes 210-A-B-C, process 400 may end (block 445). Alternatively, networkmanagement system 125 may select another light path to assign the newoptical channel (e.g., light path B-E-F-C) and return to block 405.

In block 415, network management system 125 may assign (e.g., vianetwork management module 127) an optical carrier of the selectedoptical channel to a new bandwidth location. In block 420, networkmanagement system 125 may shift traffic (e.g., via network managementmodule 127) to the optical carrier assigned to the new bandwidthlocation. In block 425, network management system 125 may turn-off(e.g., via network management module 127) the optical carrier from whichthe traffic has been moved.

In block 430, network management system 125 may determine whetheranother optical carrier for this optical channel needs to be relocated.Depending on, among other things, the number of optical carriersassociated with the optical channel, the amount of spectrum needed forthe new optical channel, the bandwidth/channel allocation imprints,etc., network management system 125 may repeat blocks 415 through 425.If it is determined that another optical carrier for the optical channelis to be relocated (block 430—YES), process 400 continues to block 415.If it is determined that another carrier for the optical channel is notto be relocated (block 430), it is determined whether another opticalchannel is to be relocated (block 435). For example, depending on, amongother things, the amount of spectrum needed for the new optical channeland the bandwidth/channel allocation imprints, network management system125 may determine whether additional defragging is to be performed.

If it is determined that another optical channel is to be relocated(block 435—YES), process 400 continues to block 415. If it is determinedthat another optical channel is not to be relocated (e.g., sufficientcontiguous, unused bandwidth does not exist nor can be created), process400 ends (block 440).

Although FIG. 4 illustrates an exemplary process 400 for defraggingchannel allocation(s) to achieve optimal spectral usage, according toother implementations, process 400 may include additional operations,fewer operations, and/or different operations than those illustrated inFIG. 4 and described. For example, network management system 125configures the new optical channel (via network management module 127)to the contiguous, unused bandwidth created by the defragging process.

FIG. 5 is a flow diagram illustrating an exemplary process 500 to set upan optical channel based on light path distance. In block 505, networkmanagement system 125 may determine whether there is an available lightpath with a shorter distance for an optical channel. For example,network management system 125 may select a particular light path todetermine whether there is an alternate, shorter light path for theselected optical channel. By way of example, referring to FIG. 2, assumethat there is a 2-Tb/s channel via light path A-B-E-H-G in which DP-QPSKis used for each optical carrier and the total bandwidth used is 500GHz. Subsequently, a new light path A-G is created.

If it is determined that there is an alternate, shorter light path forthe selected optical channel (block 505—YES), the available bandwidthfor the shorter light path is identified (block 510). For example,network management system 125 determines that light path A-G is shorterthan light path A-B-E-H-G. Network management system 125 identifies theavailable bandwidth with respect to the light path A-G. In this example,network management system 125 identifies the available bandwidth is 300GHz and process 500 continues to block 515.

If it is determined that there is not another, shorter light path for anoptical channel (block 505—NO), it is determined whether there isanother optical channel to consider (block 530). If there is anotheroptical channel to consider (block 530—YES), process 500 continues toblock 505. If there is not another optical channel to consider (block530—NO), process 500 ends (block 535).

In block 515, it is determined whether a higher order modulation formatusing less available bandwidth (e.g., relative to the bandwidthallocated for the existing optical channel) for the optical channel maybe used. For example, network management system 125 determines whether ahigher order modulation format can be used in the available 300 GHz oflight path A-G. In this example, network management system 125determines that the Dual Polarization 16 Quadrature Amplitude Modulation(DP-16 QAM) modulation format may be used for light path A-G in which250 GHz of optical bandwidth may be used to yield a 2-Tb/s channel.

As illustrated in FIG. 5, if it is determined that a higher ordermodulation format may not be used (block 515—NO), process 500 maycontinue to block 530. However, if it is determined that a higher ordermodulation format may be used (block 515—YES), the alternate, shorterlight path using the higher order modulation format is selected for theoptical channel (block 520). For example, network management system 125configures (e.g., via network management module 127) the selectedoptical channel via the alternate, shorter light path A-G in which theoptical bandwidth is 250 GHz using DP-16 QAM.

In block 525, it is determined whether there is another optical channelto consider. If there is another optical channel to consider (block525—YES), process 500 continues to block 505. If there is not anotheroptical channel to consider (block 525—NO), process 500 ends (block540).

Although FIG. 5 illustrates an exemplary process 500 to set up anoptical channel based on light path distance, according to otherimplementations, process 500 may include additional operations, feweroperations, and/or different operations than those illustrated in FIG. 5and described.

The foregoing description of implementations provides illustration, butis not intended to be exhaustive or to limit the implementations to theprecise form disclosed. Accordingly, modifications to theimplementations described herein may be possible.

According to an exemplary embodiment described, an optical transportchannel may no longer have fixed number with respect to the followingparameters: the number of optical carriers, level of modulation formatsof the optical carriers, total optical bandwidth of an optical channel,the central frequency of an optical channel, and a total number ofoptical channels in a optical transport system.

The terms “a,” “an,” and “the” are intended to be interpreted to includeone or more items. Further, the phrase “based on” is intended to beinterpreted as “based, at least in part, on,” unless explicitly statedotherwise. The term “and/or” is intended to be interpreted to includeany and all combinations of one or more of the associated items.

In addition, while a series of blocks is described with regard to theprocesses illustrated in FIGS. 3-5, the order of the blocks may bemodified in other implementations. Further, non-dependent blocks may beperformed in parallel. Additionally, with respect to other processesdescribed in this description, the order of operations may be differentaccording to other implementations, and/or operations may be performedin parallel.

An embodiment described herein may be implemented in many differentforms of software and/or firmware executed by hardware. For example, aprocess or a function may be implemented as “logic” or as a “component.”The logic or the component may include, for example, hardware, acombination of hardware and software, a combination of hardware andfirmware, or a combination of hardware, software, and firmware. By wayof example, hardware may include a processor. The processor may include,for example, one or multiple processors, microprocessors, dataprocessors, co-processors, multi-core processors, application specificintegrated circuits (ASICs), controllers, programmable logic devices,chipsets, field programmable gate arrays (FPGAs), system on chips(SoCs), programmable logic devices (PLSs), microcontrollers, applicationspecific instruction-set processors (ASIPs), central processing units(CPUs) to interpret and/or execute instructions and/or data.

In the preceding specification, various embodiments have been describedwith reference to the accompanying drawings. It will, however, beevident that various modifications and changes may be made thereto, andadditional embodiments may be implemented, without departing from thebroader scope of the invention as set forth in the claims that follow.The specification and drawings are accordingly to be regarded asillustrative rather than restrictive.

In the specification and illustrated by the drawings, reference is madeto “an exemplary embodiment,” “an embodiment,” “embodiments,” etc.,which may include a particular feature, structure or characteristic inconnection with an embodiment(s). However, the use of the phrase or term“an embodiment,” “embodiments,” etc., in various places in thespecification does not necessarily refer to all embodiments described,nor does it necessarily refer to the same embodiment, nor are separateor alternative embodiments necessarily mutually exclusive of otherembodiment(s). The same applies to the term “implementation,”“implementations,” etc.

No element, act, operation, or instruction described in the presentapplication should be construed as critical or essential to theembodiments described herein unless explicitly described as such.

1. An optical node comprising: one or more transponders; and areconfigurable optical add-drop multiplexer (ROADM) that isdirectionless, colorless, contentionless, and gridless comprising:flexible spectrum selective switches; and add/drop ports, wherein theone or more transponders and the ROADM are configured to: transmit,receive, and switch a non-fixed number of optical channels based on anoptical network demand, wherein an optical bandwidth associated witheach optical channel is non-fixed.
 2. The optical node of claim 1,further comprising: power splitters; and wherein the ROADM is configuredto: add or drop the non-fixed number of optical channels according tothe non-fixed optical bandwidth associated with each optical channel,and wherein no channel spacing is used relative to at least two of thenon-fixed number of optical channels.
 3. The optical node of claim 1,wherein the optical channels are dense wavelength division multiplexingoptical channels.
 4. The optical node of claim 1, further comprising: anetwork management module comprising: one or more processors toconfigure the network management module to: configure the non-fixednumber of optical channels via the one or more transponders and theROADM, wherein the number of optical carriers for each optical channeland a data rate for each optical channel is adjusted dynamically basedon the optical network demand.
 5. The optical node of claim 4, whereinthe one or more transponders are configured to: set a data rate for eachoptical channel; set a number of optical carriers for each opticalchannel; set a modulation format for each optical carrier; set a totalbandwidth for each optical channel; and set a starting frequency and anending frequency for each optical channel based on instructions from thenetwork management module.
 6. An optical communication systemcomprising: a transport system comprising optical nodes connected tooptical fibers, wherein each optical node comprises: a networkmanagement module; one or more transponders; a reconfigurable opticaladd-drop multiplexer (ROADM) that is directionless, colorless,contentionless, and gridless; and the transport system furthercomprising: a network management system comprising: one or more memoriesstoring instructions; and one or more processors to execute theinstructions and configure the network management system to: configurethe one or more transponders and the ROADM of the optical nodes, via thenetwork management module, to: transmit, receive, and switch a non-fixednumber of optical channels based on an optical network demand, whereinan optical bandwidth associated with each optical channel is non-fixed.7. The optical communication system of claim 6, wherein the one or moretransponders are configured to: set a data rate for each opticalchannel; set a number of optical carriers for each optical channel; seta modulation format for each optical carrier; set a total bandwidth foreach optical channel; and set a starting frequency and an endingfrequency for each optical channel according to a gridless use of anoptical spectrum.
 8. The optical communication system of claim 6,wherein the ROADM comprises: flexible spectrum selective switches; andadd/drop ports, wherein the flexible spectrum selective switches areconfigured to: switch the non-fixed number of optical signals to theadd/drop ports according to the non-fixed optical bandwidth associatedwith each optical channel.
 9. The optical communication system of claim6, wherein the ROADM comprises: power splitters, and wherein no channelspacing is used relative to at least two of the non-fixed number ofoptical channels.
 10. The optical communication system of claim 6,wherein the transport system includes a dense wavelength divisionmultiplexing transport system.
 11. A method comprising: examining abandwidth allocation of an optical spectrum; identifying whether anotherbandwidth location can be used to service an optical channel based onwhether an assignment of the optical channel to the other bandwidthlocation creates a contiguous amount of unused bandwidth that is greaterthan a contiguous amount of unused bandwidth if the optical channel isnot assigned to the other bandwidth location; assigning one or moreoptical carriers belonging to the optical channel to the other bandwidthlocation when it is identified that the other bandwidth location can beused to service the optical channel and the assignment creates thecontiguous unused bandwidth that is greater than the contiguous amountof unused bandwidth if the optical channel is not assigned to the otherbandwidth location; shifting optical network traffic to the one or moreassigned optical carriers of the other bandwidth location; and releasingone or more optical carriers of the optical channel associated with anoriginal bandwidth location.
 12. The method of claim 11, wherein theother bandwidth location does not provide optical spectrum for channelspacing relative to the optical channel.
 13. The method of claim 11,further comprising: identifying whether a bandwidth location can be usedto service another optical channel based on whether a second assignmentof the other optical channel to the bandwidth location creates a secondcontiguous amount of unused bandwidth that is greater than a contiguousamount of unused bandwidth if the other optical channel is not assignedto the bandwidth location; assigning one or more optical carriersbelonging to the other optical channel to the bandwidth location when itis identified that the bandwidth location can be used to service theother optical channel and the second assignment creates the secondcontiguous amount of unused bandwidth that is greater than thecontiguous amount of unused bandwidth if the other optical channel isnot assigned to the bandwidth location; shifting optical network trafficto the one or more assigned optical carriers of the bandwidth location;and releasing one or more optical carriers of the other optical channelassociated with a second original bandwidth location.
 14. The method ofclaim 11, further comprising: assigning a new optical channel to theoriginal bandwidth location, wherein the original bandwidth locationdoes not provide optical spectrum for channel spacing relative to thenew optical channel.
 15. The method of claim 11, wherein the examining,the identifying, the assigning, the shifting, and the releasing isperformed based on a proactive triggering event or a reactive triggeringevent.
 16. A method, comprising: determining a channel data rate of anoptical network traffic flow demand; identifying one or more candidatelight paths to satisfy the optical network traffic flow demand based onan identification of end nodes pertaining to the optical network trafficflow demand; selecting a modulation format for each carrier and a numberof carriers required to satisfy the optical network traffic flow demandfor each of the one or more candidate light paths; selecting a totalbandwidth for each of the one or more candidate light paths based on theselected modulation format; searching an available bandwidth for each ofthe one or more candidate light paths based on the total bandwidth;identifying whether one or more of the one or more candidate light pathsdo not have the available total bandwidth; removing the one or more ofthe one or more candidate light paths as a candidate light path if it isidentified that the one or more of the one or more light paths do nothave the available total bandwidth; and selecting one of the one or morecandidate light paths that has the available total bandwidth.
 17. Themethod of claim 16, wherein the selecting further comprises: selectingthe one of the one or more candidate light paths based on one or more ofa distance or a spectral efficiency pertaining to the one of the one ormore candidate light paths.
 18. The method of claim 16, furthercomprising: configuring a channel along the one of the one or morecandidate light paths based on the selected modulation format for eachcarrier and the number of carriers, and the available total bandwidth.19. The method of claim 18, wherein the available total bandwidth doesnot provide optical spectrum for channel spacing relative to the channel20. The method of claim 16, wherein the number of carriers is greaterthan one.
 21. A method comprising: selecting an optical channel;determining whether there is another available light path that isshorter than an existing light path being used to support the opticalchannel; identifying an available bandwidth of the other available lightwhen it is determined that there is the other available light path thatis shorter; determining whether a higher modulation format that usesless bandwidth relative to a modulation format and bandwidth being usedalong the existing light path can be used; switching the optical channelto the other available light path when it is determined that the highermodulation format that uses less bandwidth can be used; and configuringthe optical channel based on the higher modulation format.
 22. Themethod of claim 21, further comprising: repeating the method of claim 21relative to one or more other selected optical channels.
 23. The methodof claim 21, wherein optical spectrum to which the optical channel isswitched does not provide channel spacing relative to the opticalchannel.
 24. The method of claim 21, wherein method claim 21 isperformed based on a proactive triggering event or a reactive triggeringevent.
 25. The method of claim 24, wherein the reactive triggering eventincludes when a topology of an optical network changes.